Cold shock domain protein from Philosamia ricini prefers single-stranded nucleic acids binding

The cold shock proteins are evolutionarily conserved nucleic acid-binding proteins. Their eukaryotic homologs are present as cold shock domain (CSD) in Y-box proteins. CSDs too share striking similarity among different organisms and show nucleic acid binding properties. The purpose of the study was to investigate the preferential binding affinity of CSD protein for nucleic acids in Philosamia ricini. We have cloned and sequenced the first cDNA coding for Y-box protein in P. ricini; the sequence has been deposited in GenBank. Comparative genomics and phylogenetic analytics further confirmed that the deduced amino acid sequence belongs to the CSD protein family. A comparative study employing molecular docking was performed with P. ricini CSD, human CSD, and bacterial cold shock protein with a range of nucleic acid entities. The results indicate that CSD per se exhibits preferential binding affinity for single-stranded RNA and DNA. Possibly, the flanking N- and C-terminal domains are additionally involved in interactions with dsDNA or in conferring extra stability to CSD for improved binding.     

Cold shock domain protein from Philosamia ricini prefers single-stranded nucleic acids binding

The cold shock proteins are evolutionarily conserved nucleic acid-binding proteins. Their eukaryotic homologs are present as cold shock domain (CSD) in Y-box proteins. CSDs too share striking similarity among different organisms and show nucleic acid binding properties. The purpose of the study was to investigate the preferential binding affinity of CSD protein for nucleic acids in Philosamia ricini. We have cloned and sequenced the first cDNA coding for Y-box protein in P. ricini; the sequence has been deposited in GenBank. Comparative genomics and phylogenetic analytics further confirmed that the deduced amino acid sequence belongs to the CSD protein family. A comparative study employing molecular docking was performed with P. ricini CSD, human CSD, and bacterial cold shock protein with a range of nucleic acid entities. The results indicate that CSD per se exhibits preferential binding affinity for single-stranded RNA and DNA. Possibly, the flanking N- and C-terminal domains are additionally involved in interactions with dsDNA or in conferring extra stability to CSD for improved binding.     

Cold shock proteins improve E. coli cell-free synthesis in terms of soluble yields of aggregation-prone proteins

Protein folding is usually slowed-down at low temperatures, and thus low-temperature expression is an effective strategy to improve the soluble yield of aggregation-prone proteins. In this study, we investigated the effects of a variety of cold shock proteins and domains (Csps) on an Escherichia coli cell extract-based cell-free protein synthesis system (CF). Most of the 12 Csps that were successfully prepared dramatically improved the protein yields, by factors of more than 5 at 16°C and 2 at 23°C, to levels comparable to those obtained at 30°C. Their stimulatory effects were complementary to each other, while CspD and CspH were inhibitory. The Csps’ effects correlated well with their Pfam CSD family scores (PF00313.22). All of the investigated Csps, except CspH, similarly possessed RNA binding and chaperon activities and increased the messenger RNA amount irrespective of their effect, suggesting that the proper balance between these activities was required for the enhancement. Unexpectedly, the 5′-untranslated region of cspA was less effective as the leader sequence. Our results demonstrated that the use of the Csps presented in this study will provide a simple and highly effective strategy for the CF, to improve the soluble yields of aggregation-prone proteins.     

Proteomic study of cold shock protein in Bacillus stearothermophilus P1: Comparison of temperature downshifts

The thermophilic bacterium Bacillus stearothermophilus P1 is unique in its ability to thrive in extreme environments such as high temperatures or high pH conditions. The study of cold shock response is very interesting and interpreted as a shock response to express the genes involved in synthesis of specific proteins. This study investigated the study of cold shock protein of B. stearothermophilus P1 when the cell culture temperature shifted from 65 degrees C to 37 degrees C and 25 degrees C. Cell growth at 37 degrees C weakly increased in the previous 3 h and then slowly decreased. In contrast, cell growth at 25 degrees C was slowly decreased. The protein contents after temperature downshifts were analyzed by proteomic techniques using protein chip and two-dimensional (2-D) electrophoresis that are highly effective and useful for protein separation and identification. The different proteins after a temperature decrease from 65 degrees C to 37 degrees C and 25 degrees C were expressed on 2-D gel patterns and the cold shock protein was detected in the acidic area with the isoelectric point and molecular mass approximately 4.5 and 7.3 kDa, respectively. The NH(2)-terminal sequence of a major cold shock protein from B. stearothermophilus P1 was MQRGKVKWFNNEKGFGFIEVEGGSD, similar to other cold shock proteins from Bacillus sp. up to 96% identity, but different from the other bacteria with homology less than 80% identity.     

Proteomics of early and late cold shock stress on thermophilic bacterium, Thermus sp. GH5

Thermus sp. GH5 is an aerobic thermophilic bacterium with optimal growth at 70-75°C isolated from a hot spring in Ardabil, North West province of Iran. Due to industrial and biotechnological applications of thermophils, it is very important to know more about their proteomes and metabolomes. Since thermophils live in stressful environments it will be very useful to study their survival mechanisms. There are many reports on stress induced proteins, particularly the well characterized heat shock proteins, but little is known about the functions of proteins induced after a decrease in temperature. In this study, the proteomes of the thermophilic bacterium after a temperature down shift from 75°C to 45°C for 2h and 5h were investigated. We also compared protein profiles of early and late cold shock processes to that of cells grown at 75°C and identified a set of proteins, some of which are involved in metabolic processes such as fatty acid synthesis, pentose phosphate pathway, aromatic component degradation and signal transduction. Our data showed this organism could be tolerating the stress conditions by changing its metabolism and physiology.     

Comparative Protein Modeling, Prediction of Conserved Residue and Active Sites in Cold Resistant Protein Isolated from CRPF1, A Cold Tolerant Mutant of Pseudomonas fluorescens

Proteins interacting with the biological information molecules DNA and RNA play important cellular roles in all organisms. One widespread super family of proteins implicated in such function(s) is cold shock protein (CSP) that contains the cold shock domain (CSD). This work is planned to study the three-dimensional structure, conserved residues, and different active sites in the structure of cold resistant protein (CRP) from CRPF₁, cold tolerant mutant of Pseudomonas fluorescence by comparative homology modeling. Here we tried to identify crucial residues that are involved in active sites or functional sites of the protein. The study reveals that CRP represent the prototype of the CSD and share a highly similar overall fold consisting of five antiparallel β-sheets forming a β-barrel structure with surface exposed aromatic and basic residues that were responsible for nucleic acid binding properties of variable binding affinities and sequence selectivity and harbors the nucleic acid binding motifs RNP1 and RNP2 that is highly conserved in CSP family.     

CspI, the ninth member of the CspA family of Escherichia coli, is induced upon cold shock

Escherichia coli contains the CspA family, consisting of nine proteins (CspA to CspI), in which CspA, CspB, and CspG have been shown to be cold shock inducible and CspD has been shown to be stationary-phase inducible. The cspI gene is located at 35.2 min on the E. coli chromosome map, and CspI shows 70, 70, and 79% identity to CspA, CspB, and CspG, respectively. Analyses of cspI-lacZ fusion constructs and the cspI mRNA revealed that cspI is cold shock inducible. The 5'-untranslated region of the cspI mRNA consists of 145 bases and causes a negative effect on cspI expression at 37 degrees C. The cspI mRNA was very unstable at 37 degrees C but was stabilized upon cold shock. Analyses of the CspI protein on two-dimensional gel electrophoresis revealed that CspI production is maximal at or below 15 degrees C. Taking these results together, E. coli possesses a total of four cold shock-inducible proteins in the CspA family. Interestingly, the optimal temperature ranges for their induction are different: CspA induction occurs over the broadest temperature range (30 to 10 degrees C), CspI induction occurs over the narrowest and lowest temperature range (15 to 10 degrees C), and CspB and CspG occurs at temperatures between the above extremes (20 to 10 degrees C).     

乳酸乳球菌中冷休克蛋白基因的高效表达及其抗冻保护作用

[目的]微生物在适应外界环境急剧降温的条件下都会发生应激反应,产生一系列蛋白质被称为冷休克蛋白.冷休克蛋白对乳酸菌适应低温环境和增强抗冻能力方面发挥着重要作用.本文目的是为了研究乳酸乳球菌中冷休克蛋白CspC、CspD的作用.[方法]将冷休克蛋白CspC、CspD基因分别重组到质粒pNZ8148,转化乳酸乳球菌NZ9000后,加入Nisin诱导,对表达产物进行SDS-PAGE电泳分析,比较重组菌与空白菌在30℃条件下菌体生长差异及反复冻融活菌数的差异.[结果]得出CspC、CspD的相对分子量分别为7.0、6.2 kDa.[结论]CspC使菌体更加迅速的恢复了生长;冷休克蛋白CspD增强了菌体的抗冻存活率(增加了30～40倍).     

Draft Genome Sequence of a Psychrotolerant Sulfur-Oxidizing Bacterium, Sulfuricella denitrificans skB26, and Proteomic Insights into Cold Adaptation

Except for several conspicuous cases, very little is known about sulfur oxidizers living in natural freshwater environments. Sulfuricella denitrificans skB26 is a psychrotolerant sulfur oxidizer recently isolated from a freshwater lake as a representative of a new genus in the class Betaproteobacteria. In this study, an approximately 3.2-Mb draft genome sequence of strain skB26 was obtained. In the draft genome, consisting of 23 contigs, a single rRNA operon, 43 tRNA genes, and 3,133 coding sequences were identified. The identified genes include those required for sulfur oxidation, denitrification, and carbon fixation. Comparative proteomic analysis was conducted to assess cold adaptation mechanisms of this organism. From cells grown at 22°C and 5°C, proteins were extracted for analysis by nano-liquid chromatography-electrospray ionization-tandem mass spectrometry. In the cells cultured at 5°C, relative abundances of ribosomal proteins, cold shock proteins, and DEAD/DEAH box RNA helicases were increased in comparison to those at 22°C. These results suggest that maintenance of proper translation is critical for growth under low-temperature conditions, similar to the case for other cold-adapted prokaryotes.     

Cold shock domain of the human Y-box protein YB-1. Backbone dynamics and equilibrium between the native state and a partially unfolded state

The three-dimensional structure of the central cold shock domain (CSD) of the human Y-box protein (YB-1 CSD) is virtually identical to those available for the bacterial cold shock proteins (Csp's). We have further characterized YB-1 CSD by studying its dynamics by nuclear magnetic resonance. The observed structural similarity is reflected in the backbone dynamics, which for YB-1 CSD is very similar to that of the Escherichia coli protein CspA. The rotational correlation time of YB-1 CSD shows that it is a monomer. This indicates that the dimerization observed for the YB-1 protein is not caused by its CSD, but involves other parts of this protein. The YB-1 CSD is only marginally stable as are the mesophilic bacterial Csp's. In contrast to the rapid two-state folding of the bacterial Csp's, the formation of the native form of YB-1 CSD is slow and at least a three-state process. The NMR experiments revealed the presence of a second state of YB-1 CSD in equilibrium with the native form. The exchange rates from and to the folded state are in the order of 0.2 and 0.5 s(-1), respectively. Relaxation experiments indicated that the second state is a highly flexible, partly structured molecule.     

A family of cold shock proteins in Bacillus subtilis is essential for cellular growth and for efficient protein synthesis at optimal and low temperatures

Like other bacteria, Bacillus subtilis possesses a family of homologous small acidic proteins (CspB, CspC and CspD, identity > 70%) that are strongly induced in response to cold shock. We show that deletion of cspC or cspD genes did not result in a detectable phenotype; in contrast, csp double mutants exhibited severe reduction in cellular growth at 15°C as well as at 37°C, including impairment of survival during the stationary phase. Two-dimensional gel analysis showed that protein synthesis was deregulated in csp double mutants and that the loss of one or two CSPs led to an increase in the synthesis of the remaining CSP(s) at 37°C and after cold shock, suggesting that CSPs down-regulate production of members from this protein family. A cspB/C/D triple mutant (64BCDbt) could only be generated in the presence of cspB in trans on a plasmid that was not lost, in spite of lack of antibiotic pressure, indicating that a minimum of one csp gene is essential for viability of B . subtilis . After cold shock, synthesis of CspB in 64BCDbt was drastically lower than in wild-type cells accompanied by cessation in growth and strong reduction in general protein synthesis. As CspB, CspC and CspD are shown to bind to RNA in a co-operative and interactive manner, CSPs are suggested to function as RNA chaperones facilitating the initiation of translation under optimal and low temperatures.     

The NMR solution structures of the five constituent cold-shock domains (CSD) of the human UNR (upstream of N-ras) protein

Upon cold shock, the amounts of most proteins dramatically decrease from normal levels, but those of cold shock proteins (CSPs) and proteins containing cold-shock domains (CSDs) greatly increase. Although their biological function is still not completely clear, cold-shock proteins might control translation via RNA chaperoning. Many cold-shock proteins contain the motifs (Y/F)GFI and (V/F)(V/F)H, which are known as ribonucleoprotein (RNP)-1 and RNP-2 motifs implicated in RNA/DNA binding. We determined the solution NMR structures of all five constituent CSDs of the human UNR (upstream of N-ras) protein. The spatial arrangements of the sidechains in the RNP-1 and RNP-2 motifs are mostly conserved; however, the conformations of the following residues in the first CSD are different: F43 and H45 (the first phenylalanine residue and the histidine residue in the putative binding site RNP-2) and Y30 (the first residue in the putative binding site RNP-1). F43 and H45 affect each other, and H45 is further influenced by C46. The altered binding site of the first CSD, and its putatively enhanced intrinsic stability, may provide an explanation for the observation that the first CSD has 20-fold higher RNA-binding activity than the fifth CSD. It also lends support to the hypothesis that the UNR protein arose by repeated duplication of a protein that originally contained just one CSD, and that the proto-UNR protein acquired cysteine C46 by mutation during evolution.     

Cold shock domain proteins in the extremophyte Thellungiella salsuginea (salt cress): gene structure and differential response to cold

Four genes encoding cold shock domain (CSD) proteins have been identified in salt cress [Thellungiella salsuginea (halophila), an extremophyte currently recognized as a promising model for studying stress tolerance]. The deduced proteins prove highly homologous to those of Arabidopsis thaliana (up to 95% identity) and are accordingly enumerated TsCSDP1-TsCSDP4; after the N-proximal conserved CSD, they have respectively 6, 2, 7, and 2 zinc finger motifs evenly spaced by Gly-rich stretches. Much lower similarity (approximately 45%) is observed in the regions upstream of TATA-box promoters of TsCSDP1 vs. AtCSP1, with numerous distinctions in the sets of identifiable cis-regulatory elements. Plasmid expression of sCSDP1 rescues a cold-sensitive cup-lacking mutant of Escherichia coli, confirming that the protein is functional. In leaves of salt cress plants under normal conditions, the mRNA levels for the four TsCSDPs relate as 10: 27: 1: 31. Chilling to 4 degrees C markedly alters the gene expression; the 4-day dynamics are different for all four genes and quite dissimilar from those reported for their Arabidopsis homologues under comparable conditions. Thus, the much greater cold hardiness of Thellungiella vs. Arabidopsis cannot be explained by structural distinctions of its CSDPs, but rather may be due to expedient regulation of their expression at low temperature.     

Y-box Binding Protein 1: Looking Back to the Future

Biochemistry (Moscow) - Y-box binding protein 1 is a member of the cold shock domain (CSD) protein family and one of the most studied proteins associated with a large number of human diseases. This...     

Complementation of cold shock proteins by translation initiation factor IF1 in vivo.

The cold shock response in both Escherichia coli and Bacillus subtilis is induced by an abrupt downshift in growth temperature and leads to a dramatic increase in the production of a homologous class of small, often highly acidic cold shock proteins. This protein family is the prototype of the cold shock domain (CSD) that is conserved from bacteria to humans. For B. subtilis it has been shown that at least one of the three resident cold shock proteins (CspB to D) is essential under optimal growth conditions as well as during cold shock. Analysis of the B. subtilis cspB cspC double deletion mutant revealed that removal of these csp genes results in pleiotropic alteration of protein synthesis, cell lysis during the entry of stationary growth phase, and the inability to differentiate into endospores. We show here that heterologous expression of the translation initiation factor IF1 from E. coli in a B. subtilis cspB cspC double deletion strain is able to cure both the growth and the sporulation defects observed for this mutant, suggesting that IF1 and cold shock proteins have at least in part overlapping cellular function(s). Two of the possible explanation models are discussed.     

植物冷激蛋白的研究进展

冷激蛋白是存在于细菌、植物与动物中的一类高度保守的核酸结合蛋白,其通过RNA分子伴侣活性参与转录、翻译及生长发育和逆境胁迫应答等细胞生理活动。本文主要从植物冷激蛋白的结构、表达模式、生物学功能以及应用前景等几个方面介绍了植物冷激蛋白的研究进展。     

RNA binding specificity of Unr, a protein with five cold shock domains

The human unr gene encodes an 85 kDa protein which contains five cold shock domains (CSD). The capacity of Unr to interact in vitro with RNA and its intracellular localization suggest that Unr could be involved in some aspect of cytoplasmic mRNA metabolism. As a step towards identification of Unr mRNA targets, we investigated the RNA-binding specificity of Unr by an in vitro selection approach (SELEX). Purine-rich sequences were selected by Unr, leading to the identification of two related consensus sequences characterized by a conserved core motif AAGUA/G or AACG downstream of a purine stretch. These consensus sequences are 11-14 nt long and appear unstructured. RNAs containing a consensus sequence were bound specifically by Unr with an apparent dissociation constant of 1 x 10(-8) M and both elements, the 5' purine stretch and the core motif, were shown to contribute to the high affinity. When the N-terminal and C-terminal CSD were analyzed individually, they exhibited a lower affinity than Unr for winner sequences (5- and 100-fold, respectively) but with similar binding specificity. Two combinations of CSDs, CSD1-2-3 and CSD1*2-3-4-5 were sufficient to achieve the high affinity of Unr, indicating some redundancy between the CSDs of Unr for RNA recognition. The SELEX-generated consensus motifs for Unr differ from the AACAUC motif selected by the Xenopus Y-box factor FRGY2, indicating that a diversity of RNA sequences could be recognized by CSD-containing proteins.